Diurnal and seasonal dynamics of soil respiration in desert shrubland of Artemisia Ordosica on Ordos Plateau of Inner Mongolia, China

Zhao Jin; Yu-chun Qi; Yun-she Dong

doi:10.1007/s11676-007-0047-3

Journal of Forestry Research ›› 2007, Vol. 18 ›› Issue (3) : 231 -235. DOI: 10.1007/s11676-007-0047-3

Article

Diurnal and seasonal dynamics of soil respiration in desert shrubland of Artemisia Ordosica on Ordos Plateau of Inner Mongolia, China

Author information +

History +

PDF

Abstract

The diurnal and seasonal dynamics of soil respiration in the A. ordosica shrubland on Ordos Plateau were investigated in the growing season (May–October) of 2006 and their environmental driving factors were also analyzed. Results indicated that diurnal dynamics of soil respiration rate and its temperature dependence showed some discrepancy in two different growth stages (the vegetative growth stage and the reproductive growth stage). During the vegetative growth stage, the diurnal variation of soil respiration was slight and not correlated with the daily temperature change, but during the reproductive growth stage, the daily respiration variation was relatively large and significantly correlated with the diurnal variation of air and soil temperature. In the growing season, the peak value of soil respiration occurred at July and August because of the better soil water-heat conditions and their optimal deployment in this period. In the shrubland ecosystem, precipitation was the switch of soil respiration pulses and can greatly increase soil respiration rates after soil rewetting. Moreover, the soil respiration rates in the growing season and the air temperature and soil surface water content were closely correlated (p<0.05) each other. The stepwise regression model indicated that the variation of soil surface moisture accounted for 41.9% of the variation in soil respiration (p<0.05).

Keywords

Soil respiration / Shrubland / Artemisia ordosica / Ordos Plateau

Cite this article

Download citation ▾

Zhao Jin, Yu-chun Qi, Yun-she Dong. Diurnal and seasonal dynamics of soil respiration in desert shrubland of Artemisia Ordosica on Ordos Plateau of Inner Mongolia, China. Journal of Forestry Research, 2007, 18(3): 231-235 DOI:10.1007/s11676-007-0047-3

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Archer S., Boutton T.W., Hibbard K.A. et al. Schulze E., Heimann M., Harrison S. et al. Trees in grasslands: biogeochemical consequences of woody plant expansion Global biogeochemical cycles in the climate system. California, 2001 USA: A Harcourt Science and Technology Company 115-138.

[2]	Asner G.P., Archer S.A., Hughes R.F. et al. Net changes in regional woody vegetation cover and carbon storage in North Texas rangelands, 1937–1999 Glob Change Biol., 2003, 9(3): 316-335.

[3]	Austin A.T., Yahdjian L., Stark J.M. et al. Water pulses and biogeochemical cycles in arid and semiarid ecosystems Oecologia, 2004, 141(2): 221-235.

[4]	Davidson E.A., Belk E., Boone R. D. Soil water content and temperature as independent or confounded factors controlling soil respiration in a temperate mixed hardwood forest Glob Change Biol., 1998, 4(2): 217-227.

[5]	Dong Y.S., Qi Y.C., Liu J.Y. et al. Variation characteristics of soil respiration fluxes in four types of grassland communities under different precipitation intensity Chin Sci Bull, 2005, 50(6): 583-591.

[6]	Dong Y.S., Qi Y.C., Luo J. et al. Experimental study on N₂O and CH₄ fluxes from the dark coniferous forest zone soil of the Gongga Mountain, China Sci China Ser D., 2003, 46(3): 285-295.

[7]	Dong Y.S., Zhang S., Qi Y.C. et al. Fluxes of CO₂, N₂O and CH₄ from a typical temperate grassland in Inner Mongolia and its daily variation Chin Sci Bull, 2000, 45(3): 1590-1594.

[8]	Du R., Lu D.R., Wang G.C. Diurnal, seasonal, and inter-annual variations of N₂O fluxes from native semi-arid grassland soils of inner Mongolia Soil Biol. Biochem., 2006, 38(12): 3474-3482.

[9]	Fang C., Moncrieff J.B. The dependence of soil CO₂ efflux on temperature Soil Biol. Biochem., 2001, 33(2): 155-165.

[10]	Fang C., Smith P., Moncrieff J.B. et al. Similar response of labile and resistant soil organic matter pools to changes in temperature Nature, 2005, 433(7021): 57-59.

[11]	Grover H. D., Musick H.B. Shrubland encroachment in Southern New Mexico, U.S.A.: an analysis of desertification process in the American Southwest Clim. Change, 1990, 17(2–3): 305-330.

[12]	Hall D.O., Ojima D.S., Parton W. J. et al. Response of temperate and tropical grasslands to CO₂ and climate change J. Biogeography, 1995, 22(4–5): 537-547.

[13]	Huenneke L.F., Anderson J.P., Remmenga M. et al. Desertification alters patterns of aboveground net primary production in Chihuahuan ecosystems Glob Change Biol., 2002, 8(3): 247-264.

[14]	Jackson R.B., Banner J.L., Jobbagy E.G. et al. Ecosystem carbon loss with woody plant invasion of grasslands Nature, 2002, 418(6898): 623-626.

[15]	Kessavalou A., Doran J.W., Mosier A.R. et al. Greenhouse gas fluxes following tillage and wetting in a wheat fallow cropping system J. Environ. Qual., 1998, 27(5): 1105-1116.

[16]	Kirschbaum M.U.F. The temperature dependence of soil organic matter decomposition and the effect of global warming on soil organic C storage Soil Biol. Biochem, 1995, 27(6): 753-760.

[17]	Li X. Influence of variation of soil spatial heterogeneity on vegetation restoration Sci. China Ser. D., 2005, 48(11): 2020-2031.

[18]	Li L., Wang Q.-b., Bai Y.-f. et al. Soil respiration of A leymus chinensis grassland stand in the Xilin River Basin as affected by over-grazing and climate Acta Phytoecologica Sinica, 2000, 24(6): 680-686.

[19]	Lieth H.F.H. Patterns of primary productivity in the biosphere, 1978 Stroudsburg Pennsylvania: Dowden, Hutchinson & Ross, Inc 342

[20]

Monger H.C., Gallegos R.A. et al. Lal R., Kimbel J.M., Eswaran H. et al. Biotic and abiotic processes andrates of pedogenic carbonate accumulation in the southwestern United States-relationship to atmospheric CO₂ sequestration Global climate change and pedogenic carbonates, 2000 Florida: CRC Press 273-289.

[21]	Ogle K., Reynolds J.F. Plant responses to precipitation in desert ecosystems: integrating functional types, pulses, thresholds and delays Oecologia, 2004, 141(2): 282-294.

[22]	Qi Y.C., Dong Y.S., Liu J.Y. et al. Effect of the conversion of grassland to the spring wheat field on the CO2 emission characteristics in Inner Mongolia, China Soil Till Res., 2007, 94(2): 310-320.

[23]	Qi Y.C., Dong Y.S., Liu J.Y. et al. Daily variation characteristics of CO₂ emission fluxes and contributions of environmental factors in semi-arid grassland of Inner Mongolia, China Sci. China Ser. D., 2005, 48(7): 1052-1064.

[24]	Reynolds J.F., Kemp P.R., Ogle K. et al. Modifying the ‘pulse-reserve’ paradigm for deserts of North America: precipitation pulses, soil water, and plant responses Oecologia, 2004, 141(2): 194-210.

[25]	Schlesinger W.H. The formation of caliche in soils of the Mojave Desert, California Geochim Comochim Acta, 1985, 49(1): 57-66.

[26]	Schlesinger W.H., Pilmanis A.M. Plant-soil interactions in deserts Biogeochemistry, 1998, 42(1–2): 169-187.

[27]	Scott R.L., Huxman T.E., Williams D.G. et al. Ecohydrological impacts of woody-plant encroachment: seasonal patterns of water and carbon dioxide exchange within a semiarid riparian environment Glob Change Biol., 2006, 12(2): 311-324.

[28]	Scurlock J.M.O., Hall D.O. The global carbon sink: a grassland perspective Glob Change Biol., 1998, 4(2): 229-233.

[29]	Sponseller R.A. Precipitation pulses and soil CO₂ flux in a Sonoran Desert ecosystem Glob Change Biol., 2007, 13(2): 4 26-436.

[30]	Wang Y., Wang M.-x., Hu Y.-q. et al. Study on relationship between the variations of greenhouse gases efflux/uptake and the key environmental factors in Mongolia semi-arid grasslands Clim Environ Res., 2002, 7(3): 295-310.

[31]	Xiong X., Han X.-g., Bao Y.-j. Discussion on the research into sandy desertification, accompanying by thicketization of semiarid grasslands in Inner Mongolia, China Acta Prataculturae Sinica, 2005, 14(5): 1-5.

[32]	Zhao L., Li Y.N., Xu S.X. et al. Diurnal, seasonal and annual variation in net ecosystem CO2 exchange of an alpine shrubland on Qinghai-Tibetan plateau Glob. Change Biol., 2006, 12(10): 1940-1953.

[33]	Zheng Y.R., Xie Z.X., Jiang L.H. et al. Model simulation and comparison of the ecological characteristics of three degraded grassland types in China Belg. J. Bot., 2005, 138(2): 109-118.

[34]	Zou J.W., Huang Y., Zheng X.H. et al. Static opaque chamber-based technique for determination of net exchange of CO2 between terrestrial ecosystem and atmosphere Chin. Sci. Bull., 2004, 49(4): 381-388.